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Wireless Power Transfer for E-Mobility
Fundamentals and Design Guidelines for Wireless Charging of Electric Vehicles
- 1st Edition - November 29, 2023
- Authors: Mauro Feliziani, Tommaso Campi, Silvano Cruciani, Francesca Maradei
- Language: English
- Paperback ISBN:9 7 8 - 0 - 3 2 3 - 9 9 5 2 3 - 8
- eBook ISBN:9 7 8 - 0 - 3 2 3 - 9 9 5 2 4 - 5
Wireless Power Transfer for e-Mobility: Fundamentals and Design Guidelines for Wireless Charging of Electric Vehicles provides a comprehensive resource for researchers and engin… Read more
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Request a sales quoteWireless Power Transfer for e-Mobility: Fundamentals and Design Guidelines for Wireless Charging of Electric Vehicles provides a comprehensive resource for researchers and engineers engaged in the development of automotive WPT systems.
The book opens with an overview of wireless technologies for power transfer and their evolution over time, then focusing on the application of this technology to electric mobility highlighting its importance in terms of impact and perspectives on the development of sustainable transport and autonomous driving. Chapters discuss the fundamentals of electromagnetic field in WPT systems and the circuit modelling. In addition, they examine core current electric vehicle systems and present-day automotive WPT standards. Design techniques of magnetic couplers, including compensation networks are explored in-depth alongside power electronics techniques for automotive WPT systems. Both stationary and dynamic automotive WPT systems are rigorously assessed. Finally, the problems of electromagnetic compatibility and electromagnetic field safety are described with particular attention to shielding techniques for the mitigation of magnetic field emissions.
Addressing essential knowledge from foundational to advanced levels, Wireless Power Transfer for e-Mobility provides practical guidance to engineers and researchers developing the future of electric mobility.
- Provides an advanced foundation for research and current industrial applications in automotive WPT systems
- Develops proven methodologies linked to some case studies using examples drawn from global practice
- Explores the role of WPT in near-future mobility scenarios, with featured coverage of electrified transportation
- Includes an extensive usage of equations from MATLAB, Spice and COMSOL
Graduate students and early career researchers investigating near-field wireless power transmission, e-mobility and CASE engineering, and in electrical and electronic engineering. Technicians in industry and practicing power engineers
- Cover image
- Title page
- Table of Contents
- Copyright
- Preface
- Chapter 1. Introduction to wireless power transfer for e-mobility
- 1.1. Introduction
- 1.2. Historical background
- 1.3. Basic principles of WPT technologies
- 1.4. Performance of WPT technologies
- 1.5. E-mobility
- 1.6. Static and dynamic WPT systems in automotive
- 1.7. Future scenarios
- Chapter 2. Fundamental theory of inductive WPT
- 2.1. Wireless power transfer
- 2.2. Inductive power transfer
- 2.3. Magnetic resonant coupling
- 2.4. Performance of a WPT system
- 2.5. Compensation topology
- 2.6. Power electronics
- 2.7. Basic WPT design
- Chapter 3. Magnetic field in a WPT system
- 3.1. Electromagnetic field equations
- 3.2. Analytical solution of field equations
- 3.3. Numerical solution of field equations
- 3.4. Postprocessing of field simulations
- 3.5. Simulation by commercial software tools
- Chapter 4. Circuit models of a WPT system
- 4.1. Equivalent circuit of a WPT system
- 4.2. Circuit models of two coupled coils
- 4.3. Circuit models of a resonant coupler
- 4.4. Circuit models of a multicoil system
- 4.5. Driving and receiving electronic units
- 4.6. Battery cell modeling
- 4.7. SPICE analysis
- 4.8. MATLAB simulation of resonant coupler
- 4.9. Appendix—conversion of two-port network parameters
- Chapter 5. Magnetic couplers for automotive WPT systems
- 5.1. Coupled coils: fundamentals, definitions and equations
- 5.2. Self and mutual inductances
- 5.3. Analytical solutions of coils in free space
- 5.4. Magnetic materials
- 5.5. WPT pads
- 5.6. Conductors
- 5.7. Litz wire
- Chapter 6. Compensation networks of automotive WPT system
- 6.1. Why use compensation networks?
- 6.2. Mono-resonant compensation topologies
- 6.3. Multiresonant compensation networks
- 6.4. Comparison of compensation topologies
- 6.5. Application case: S/P and LCC compensations for WPT automotive
- Chapter 7. Power electronics in WPT systems
- 7.1. Introduction
- 7.2. AC/DC converter (rectifier)
- 7.3. DC/AC converter (inverter)
- 7.4. High frequency rectifier
- 7.5. DC/DC converter (voltage regulator)
- 7.6. Power control
- Chapter 8. Stationary and dynamic WPT systems for electric vehicles
- 8.1. Introduction to electric vehicles
- 8.2. Stationary WPT
- 8.3. Dynamic WPT systems
- 8.4. Light electric vehicles
- Chapter 9. Magnetic field shielding for WPT systems
- 9.1. Introduction to electromagnetic shielding
- 9.2. Conductive shielding
- 9.3. Magnetic shielding
- 9.4. Shielding coils
- 9.5. Shielding of WPT systems
- 9.6. Shielding design for WPT systems
- 9.7. Design of passive shielding coils
- 9.8. Design of active coils
- 9.9. Other mitigation techniques
- Chapter 10. Electromagnetic field safety of automotive WPT systems
- 10.1. EMF safety principles
- 10.2. EMF safety standards and regulations
- 10.3. Compliance assessment with reference levels
- 10.4. Compliance assessment with basic restrictions
- 10.5. Test case study: EMF safety in an automotive WPT system
- Chapter 11. Electromagnetic compatibility of automotive WPT systems
- 11.1. Introduction to electromagnetic compatibility
- 11.2. Electromagnetic compatibility of WPT systems
- 11.3. EMC standards for automotive WPT
- 11.4. Component-level EMC testing
- 11.5. Vehicle-level EMC testing
- 11.6. Wireless power transmission and radio regulations
- 11.7. Interference on active implantable medical devices
- Index
- No. of pages: 414
- Language: English
- Edition: 1
- Published: November 29, 2023
- Imprint: Academic Press
- Paperback ISBN: 9780323995238
- eBook ISBN: 9780323995245
MF
Mauro Feliziani
Mauro Feliziani is Professor of Electrical Engineering at University of L’Aquila, Italy, from 1994. From 1987 to 1994 he was with the University of Rome “La Sapienza” as a Researcher (1987-1990), Assistant Professor (1990-1992) and Associate Professor (1992-1994). He is author or co-author of around 200 papers published mainly in the fields of electromagnetic compatibility (EMC) and wireless power transfer. In 1994 he was co-founder of EMC Europe Symposium and Chair of the International Steering Committee in 2012-2015. He was the General Chair of the EMC Europe Symposium in 2002, 2005 and 2020, and Technical Program Committee Chair in 2012. He was Associate Editor of the IEEE Transactions on EMC from 1995 to 2000. He was Guest Editor of Special Issue in IEEE Transactions on Magnetics in 2002 and Energies in 2018. He was the recipient of several awards in the field of EMC, WPT systems and numerical methods.
Affiliations and expertise
Professor, Electrical Engineering, University of L’Aquila, L’Aquila, ItalyTC
Tommaso Campi
Tommaso Campi received the Laurea degree in telecommunication engineering from the University of L’Aquila, Italy, in 2013 and the PhD degree in electrical engineering in 2017, both at the University of L’Aquila, L’Aquila, Italy. He is currently a researcher RTD-a at the University of L’Aquila. His research interests include wireless power transfer and electromagnetic compatibility. He was the recipient of several awards in the field of the WPT systems.
Affiliations and expertise
Assistant Professor, Electrical Engineering, University of L’Aquila, L’Aquila, Italy.SC
Silvano Cruciani
Silvano Cruciani received the Laurea degree in information and automation engineering in 2010 and the PhD degree in electrical engineering in 2015, both at the University of L’Aquila, L’Aquila, Italy. He was a post-doctoral researcher at the University of L’Aquila and Sapienza University of Rome. He is currently RTD-b researcher at the Tor Vergata University of Rome. His main research interests include numerical methods, electromagnetic wave propagation in complex media and wireless power transfer.
Affiliations and expertise
Assistant Professor, Electrical Engineering, Tor Vergata University, Rome, Italy.FM
Francesca Maradei
Francesca Maradei is Professor of Electrical Engineering at Sapienza University, Italy. She received the Laurea degree in Electrical Engineering (cum laude) in 1992 and the Ph.D. degree in Electrical Engineering in 1997, both at Sapienza University of Rome. She joined the Department of Electrical Engineering at the Sapienza University in 1996 where she is currently full professor. She has authored more than 150 technical papers in the field of computational electromagnetics and EMC. She received the 2015 Laurence Cumming Award for outstanding service to the IEEE EMC society. She was the President of the IEEE Electromagnetic Compatibility Society from 2010 to 2011, and an Associate Editor of the IEEE Transactions on EMC from 1999 to 2000. She is currently a life member of the IEEE EMC Society, and a member of the EMC Europe International Steering Committee.
Affiliations and expertise
Professor of Electrical Engineering, Sapienza University of Rome, Rome, ItalyRead Wireless Power Transfer for E-Mobility on ScienceDirect